罗斯蒙特3051压力变送器快速安装指南

2012F160-11快速安装指南00825-0106-5007, Rev DC2023 年 6 月Rosemount™ 3051 压力变送器快速安装指南2023 年 6 月内容关于本指南 (3)系统准备 (5)变送器安装 (7)安全仪表系统的安装 (21)产品认证 (22)/Rosemount2023 年 6 月快速安装指南1 关于本指南本指南提供了 Rosemount 3051 压力变送器的基本安装指导。

本指南不提供组态、诊断、维护、检修、故障诊断、防爆、隔爆或本质安全 (I.S.) 安装的说明。

更多说明，请参阅 Rosemount 3051 参考手册。

本指南的电子版本也可从/Rosemount上获得。

1.1 安全信息警告爆炸爆炸可能会导致死亡或严重受伤。

在有爆炸危险的环境中安装本设备时，请务必遵守适用的当地、国家和国际标准、规范和规程。

请参阅《Rosemount 3051 参考手册》的认证部分，以了解与安全安装相关的任何限制。

在防爆/隔爆安装中，不得在设备通电的情况下拆卸变送器盖。

过程泄漏过程泄漏可能导致伤亡。

为了避免过程泄漏，请务必仅使用与相应的法兰接头配合实现密封的 O 形圈。

触电触电可能会导致死亡或严重伤害。

不得接触引线或接线端子。

引线上可能存在的高压会导致触电。

导线管/电缆入口除非另有标明，否则外壳外罩中的导线管/缆线入口将采用 ½-14NPT 型式。

在封闭这些入口时，只能使用有相容螺纹牙形的堵头、接头、密封接头或导线管。

标有 M20 的入口为 M20 x 1.5 螺纹样式。

在具有多个导线管入口的装置上，所有入口都采用相同的螺纹牙形。

在危险场所安装时，在电缆/导线管入口中仅使用已列出或通过 Ex 认证的适当堵头、密封套或转接器。

快速安装指南3快速安装指南2023 年 6 月 警告物理接触未经授权的人员可能会对最终用户的设备造成明显受损和/或误组态。

这可能是有意或无意的，需要采取相应的防护措施。

Quick Start Guide00825-0100-4803, Rev GAOctober 2021 Rosemount™ 3051S and 3051SF Series Flow Meter MultiVariable™ TransmittersQuick Start Guide October 2021 ContentsAbout this guide (3)Mount the transmitter (5)Consider housing rotation (11)Set the switches (12)Connect wiring and power up (13)Engineering Assistant installation (17)Flow configuration (19)Verifying device configuration (28)Trimming the transmitter (32)Safety instrumented systems installation (33)Product certifications (34)2Rosemount 3051SMVOctober 2021Quick Start Guide1About this guideThis guide provides basic guidelines to install the Rosemount 3051SMultiVariable Transmitter. It also provides the basic Rosemount 3051SMVconfiguration guidelines for the Rosemount 3051SFA, Rosemount 3051SFC,and Rosemount 3051SFP. It does not provide instructions for detailedconfiguration, diagnostics, maintenance, service, troubleshooting, orinstallations. Refer to the Rosemount 3051SMV Reference Manual for moreinstruction. The manual and this guide are also available electronically at/Rosemount.1.1Safety messagesWARNINGFailure to follow these installation guidelines could result in death orserious injury.Ensure only qualified personnel perform the installation.ExplosionsExplosions could result in death or serious injury.Installation of device in an explosive environment must be in accordancewith appropriate local, national, and international standards, codes, andpractices.Review the Hazardous Locations Certifications for any restrictionsassociated with a safe installation.Process leaksProcess leaks could result in death or serious injury.Install and tighten thermowells and sensors before applying pressure.Do not remove the thermowell while in operation.Conduit/cable entriesUnless marked, the conduit/cable entries in the transmitter housing usea ½–14 NPT thread form. Entries marked “M20” are M20 × 1.5 threadform. On devices with multiple conduit entries, all entries will have thesame thread form. Only use plugs, adapters, glands, or conduit with acompatible thread form when closing these entries.When installing in a hazardous location, use only appropriately listed orEx certified plugs, glands, or adapters in cable/conduit entries.Quick Start Guide3Quick Start Guide October 2021 WARNINGElectrical shockElectrical shock could cause death or serious injury.Avoid contact with the leads and terminals. High voltage that may bepresent on leads can cause electrical shock.Unless marked, the conduit/cable entries in the housing use a ½–14 NPTthread form. Entries marked “M20” are M20 × 1.5 thread form. Ondevices with multiple conduit entries, all entries will have the samethread form. Only use plugs, adapters, glands, or conduit with acompatible thread form when closing these entries.When installing in a hazardous location, use only appropriately listed orEx certified plugs, glands, or adapters in cable/conduit entries.Physical accessUnauthorized personnel may potentially cause significant damage to and/ormisconfiguration of end users’ equipment. This could be intentional orunintentional and needs to be protected against.Physical security is an important part of any security program andfundamental to protecting your system. Restrict physical access byunauthorized personnel to protect end users’ assets. This is true for allsystems used within the facility.4Rosemount 3051SMVOctober 2021Quick Start Guide 2Mount the transmitter2.1Liquid flow applicationsProcedure1.Place taps to the side of the line.2.Mount beside or below the taps.3.Mount the transmitter so that the drain/vent valves are orientedupward.AA. Direction of flow2.2Gas flow applicationsProcedure1.Place taps in the top or side of the line.Mount beside or above the taps.2.A. Direction of flowQuick Start Guide52.3Steam flow applicationsProcedure1.Place taps to the side of the line.2.Mount beside or below the taps.3.Fill impulse lines with water.AA. Direction of flow2.4Mounting bracketsFigure 2-1: Mounting Bracket – Coplanar FlangePanel mountPipe mountQuick Start Guide October 2021 6Rosemount 3051SMVFigure 2-2: Mounting Brackets – Traditional FlangePanel mountPipe mountFigure 2-3: Mounting Brackets – In-linePanel mountPipe mount2.5Bolting considerationsIf the transmitter installation requires assembly of a process flange,manifold, or flange adapters, follow these assembly guidelines to ensure atight seal for optimal performance characteristics of the transmitter. Onlyuse bolts supplied with the transmitter or sold by Emerson as spare parts.Figure 2-4 illustrates common transmitter assemblies with the bolt lengthrequired for proper transmitter assembly.October 2021Quick Start Guide Quick Start Guide7Figure 2-4: Common Transmitter AssembliesA 4 × 1.75-in.(44 mm)D4 × 1.75-in.(44 mm)4 × 2.25-in.(57 mm)C4 × 1.75-in. (44 mm) 4 × 1.50-in.(38 mm)4 × 2.88-in.(73 mm)A.Transmitter with coplanar flange B.Transmitter with coplanar flange and optional flange adapters C.Transmitter with traditional flange and optional flange adapters D.Transmitter with coplanar flange and optional Rosemount Conventional Manifold and flange adaptersNoteFor all other manifolds, contact Customer Central technical support.Bolts are typically carbon steel or stainless steel. Confirm the material byviewing the markings on the head of the bolt and referencing Table 2-1 . Ifbolt material is not shown in Table 2-1, contact the local Emersonrepresentative for more information.Use the following bolt installation procedure:Procedure1.Carbon steel bolts do not require lubrication and the stainless steelbolts are coated with a lubricant to ease installation. However, noadditional lubricant should be applied when installing either type ofbolt.2.Finger-tighten the bolts.3.Torque the bolts to the initial torque value using a crossing pattern.See Table 2-1 for initial torque value.4.Torque the bolts to the final torque value using the same crossing pattern. See Table 2-1 for final torque value.Quick Start Guide October 20218Rosemount 3051SMVOctober 2021Quick Start Guide5.Verify the flange bolts are protruding through the sensor modulebefore applying pressure (see Figure 2-5).ExampleTable 2-1: Torque Values for the Flange and Flange Adapter BoltsFigure 2-5: Proper Bolt InstallationA.BoltB.Sensor moduleQuick Start Guide92.6O-rings with flange adaptersWARNINGFailure to install proper flange adapter O-rings may cause process leaks,which can result in death or serious injury. Only use the O-ring that isdesigned for its specific flange adapter.DA.Flange adapterB.O-ring C.PTFE-based profile (square)D.Elastomer profile (round)Whenever the flange or adapters are removed, visually inspect the O-rings.Replace them if there are any signs of damage, such as nicks or cuts. If the O-rings are replaced, re-torque the flange bolts and alignment screws afterinstallation to compensate for seating of the O-rings.Quick Start Guide October 202110Rosemount 3051SMV3Consider housing rotationTo improve field access to wiring or to better view the optional LCD display:Procedure1.Loosen the housing rotation set screw.2.Turn the housing up to 180° left or right of its original (as shipped)position.3.Re-tighten the housing rotation set screw.Figure 3-1: Transmitter Housing Set ScrewA.LCD displayB.Housing rotation set screw (3/32-in.)CAUTIONDo not rotate the housing more than 180° without first performing adisassembly procedure. Over-rotation may sever the electricalconnection between the sensor module and the electronics.4Set the switchesThe transmitter’s default configuration sets the alarm condition to high (HI)and the security to off.Procedure1.If the transmitter is installed, secure the bus and remove power.2.Required: Remove the transmitter cover opposite the field terminalside. Do not remove the instrument covers in explosiveenvironments when the circuit is live.3.Slide the Security and Alarm switches into the preferred position byusing a small screwdriver.NoteThe Security switch will need to be in the off position in order to makeany configuration changes.4.Required: In order to meet explosion-proof requirements, reinstallthe housing cover and tighten so the cover is fully seated with metalto metal contact between the housing and cover. After the cover isseated properly, replace the flathead screw located on the bottom ofthe housing cover.Figure 4-1: Transmitter Switch ConfigurationA BA.SecurityB.AC Termination5Connect wiring and power upCAUTIONDo not connect the power across the test terminals. Power could damagethe test diode in the test connection. Twisted pairs yield best results. Use 24to 14 AWG wire and do not exceed 5,000 ft. (1500 m).Use the following steps to wire the transmitter:Procedure1.Remove the cover on the field terminals side of the housing.2.Connect the positive lead to the “PWR/COMM +” terminal, and thenegative lead to the “PWR/COMM –” terminal.3.If the optional process temperature input is not installed, plug andseal the unused conduit connection. If the input is being utilized, seeInstall optional process temperature input (Pt 100 RTD sensor) formore information.When the enclosed pipe plug is utilized in the conduit opening, itmust be installed with a minimum engagement of five threads tocomply with explosion-proof requirements. Refer to the Rosemount™3051SMV Reference Manual for more information.4.If applicable, install wiring with a drip loop. Arrange the drip loopso the bottom is lower than the conduit connections and thetransmitter housing.5.Reinstall the housing cover and tighten so that metal contacts metalto meet explosion-proof requirements.Figure 5-1 shows the wiring connections necessary to power aRosemount 3051SMV and enable communications with a hand-heldField Communicator.Figure 5-1: Transmitter WiringA. Power supplyNoteInstallation of the transient protection terminal block does notprovide transient protection unless the Rosemount 3051SMVhousing is properly grounded.5.1Conduit electrical connector wiring (option GE or GM)For Rosemount 3051SMV with conduit electrical connectors GE or GM, referto the cordset manufacturer’s installation instructions for wiring details. ForFM Intrinsically Safe, Division 2 hazardous locations, install in accordancewith Rosemount drawing 03151-1009 to maintain outdoor rating (NEMA®4X and IP66). See the Rosemount 3051SMV Reference Manual.5.2Power supplyThe dc power supply should provide power with less than two percent ripple.The total resistance load is the sum of the resistance of the signal leads andthe load resistance of the controller, indicator, intrinsic safety barriers, andrelated components.Figure 5-2: Load Limitation5.3Install optional process temperature input (Pt 100 RTDsensor)NoteTo meet ATEX/IECEx Flameproof certification, only ATEX/IECEx Flameproofcables (temperature input code C30, C32, C33, or C34) may be used.Procedure1.Mount the Pt 100 RTD sensor in the appropriate location.NoteUse shielded four-wire cable for the process temperatureconnection.2.Connect the RTD cable to the Rosemount 3051SMV by inserting thecable wires through the unused housing conduit and connect to thefour screws on the transmitter terminal block. An appropriate cablegland should be used to seal the conduit opening around the cable.3.Connect the RTD cable shield wire to the ground lug in the housing.Figure 5-3: RTD Wiring ConnectionA.Ground lugB.RTD cable assembly wiresC.Pt 100 RTD sensor6Engineering Assistant installationEngineering Assistant 6.1 or laterThe Rosemount 3051SMV Engineering Assistant 6.1 or later is PC-basedsoftware that performs configuration, maintenance, diagnostic functions,and serves as the primary communication interface to the transmitter withthe fully compensated mass and energy flow feature board.The Rosemount 3051SMV Engineering Assistant software is required tocomplete the flow configuration.To ensure correct operation, download the most current version of theEngineering Assistant software at /Rosemount-Engineering-Assistant.6.1System requirementsThe following are the minimum system requirements to install theRosemount 3051SMV Engineering Assistant software:•Pentium®-grade processor: 500 MHz or faster•Operating system: Windows™ XP Professional (32-bit), or Windows 7 (32-bit or 64-bit)•256 MB RAM•100 MB free hard disk space•RS232 serial port or USB port (for use with HART® modem)•CD-ROM6.2Install Rosemount 3051SMV Engineering Assistant 6.1 orlaterProcedure1.Uninstall any existing versions of Engineering Assistant 6.2.Insert the new Engineering Assistant disk into the CD-ROM.3.Windows should detect the presence of a CD and start theinstallation program. Follow the on-screen prompts to finish theinstallation. If Windows does not detect the CD, use WindowsExplorer or My Computer to view the contents of the CD-ROM, andthen double click the SETUP.EXE program.4. A series of screens (Installation Wizard) will appear and assist in theinstallation process. Follow the on-screen prompts. It isrecommended to use the default installation settings.NoteEngineering Assistant versions 6.1 or later require the use ofMicrosoft®.NET Framework version 4.0 or later. If .NET version 4.0 isnot currently installed, the software will be automatically installedduring the Engineering Assistant installation. Microsoft .NET version4.0 requires an additional 200 MB of disk space.6.3Connect to a personal computerProcedure1.Remove the cover from the field terminals side of the housing.2.Power the device as outlined in Connect wiring and power up.3.Connect the HART modem cable to the PC.4.On the side of the transmitter marked “Field Terminals,” connect themodem mini-grabbers to the two terminals marked “PWR/COMM.”unch the Engineering Assistant software. For more information onlaunching software, see Launch Engineering Assistant 6.1 or later.6.Once the configuration is complete, replace cover and tighten untilmetal contacts metal to meet explosion-proof requirements.Figure 6-1 shows how to connect a computer to a Rosemount3051SMV.Figure 6-1: Connecting a PC to the TransmitterA.Power supplyB.Modem7Flow configurationRosemount 3051SMV Engineering Assistant 6.1 or laterThe Rosemount 3051SMV Engineering Assistant is designed to guide theuser through the setup of the flow configuration for a Rosemount 3051SMV.The flow configuration screens allow the user to specify the fluid, operatingconditions, and information about the primary element, including insidepipe diameter. This information will be used by the Rosemount 3051SMVEngineering Assistant software to create flow configuration parameters thatwill be sent to the transmitter or saved for future use.Online and offline modesThe Engineering Assistant software can be used in two modes: Online andOffline. In Online mode, the user can receive the configuration from thetransmitter, edit the configuration, send the changed configuration to thetransmitter, or save the configuration to a file. In offline mode, the user cancreate a new flow configuration and save the configuration to a file or openand modify an existing file.The following pages provide instructions on creating a new flowconfiguration in offline mode. For more information on other functionality,see the Rosemount 3051SMV Reference Manual.7.1Basic navigation overviewFigure 7-1: Engineering Assistant Basic Navigation OverviewAFGHB C D E7.2Launch Engineering Assistant 6.1 or laterFlow configuration for the Rosemount 3051SMV is achieved by launchingthe Engineering Assistant software from the Start menu.Procedure1.Select the Start menu→All Programs→Engineering Assistant.Engineering Assistant will open to the screen shown in Figure 7-2.2.Select Offline button located in the lower right hand corner of thescreen shown in Figure 7-2.Figure 7-2: Engineering Assistant Device Connection Screen7.3Use Preferences tabThe Preferences tab, shown in Figure 7-3, allows you to select the preferredengineering units to display.Procedure1.Select the preferred engineering units.2.If Custom Units are selected, configure the Individual Parameters.3.Check the box if unit preferences should be retained for futureEngineering Assistant sessions.Figure 7-3: Preferences Tab7.4Select fluid for database liquid/gasThe Fluid Selection tab shown in Figure 7-4 allows the user to choose theprocess fluid.Figure 7-4: Fluid Selection TabNoteThe following example will show a flow configuration for the database gas air used with a Rosemount 405C Conditioning Orifice Plate as the primary element. The procedure to set up any other fluid with any other primary element will be similar to this example. Natural gases, custom liquids, and custom gases require additional steps during the configuration. See the Rosemount 3051SMV Reference Manual for more information. Procedure1.Engineering Assistant may open to the Preferences tab. Using the tabsat the top of the screen, navigate to the Fluid Selection tab.2.Expand the Gas category (click on the + icon).3.Expand the Database Gas category.4.Select Air from the list of database fluids.5.Enter the Nominal Operating Pressure, select the Enter or Tab key.6.Enter the Nominal Operating Temperature, select the Enter or Tab key.Engineering Assistant will automatically fill in suggested operatingranges, as shown in Figure 7-4. These values may be edited asneeded by the user.7.Verify the Reference/Atmospheric Conditions are correct for theapplication. These values may be edited as needed.NoteReference pressure and temperature values are used by EngineeringAssistant to convert the flow rate from mass units to mass unitsexpressed as standard or normal volumetric units.8.Select Next to proceed to the Fluid Properties tab.7.5Fluid propertiesNoteThe Fluid Properties tab is an optional step and is not required to complete aflow configuration.The Fluid Properties tab for the database gas air is shown in Figure 7-5. This isused to verify the properties of the chosen fluid are acceptable.To check density, compressibility, and viscosity of the selected fluid at otherpressure and temperature values, enter a Pressure and Temperature andselect Calculate.NoteChanging the pressure and temperature values on the Fluid Properties tabdoes not affect the fluid configuration.Figure 7-5: Fluid Properties Tab7.6Select primary elementThe Primary Element Selection tab shown in Figure 7-6 allows the user tochoose the primary element.Figure 7-6: Primary Element Selection TabContinuing with the example configuration:Procedure1.Expand the Conditioning Orifice Plate category.2.Select 405C/3051SFC.3.Enter the measured Meter Tube Diameter (pipe ID) at a referencetemperature. If the meter tube diameter cannot be measured, selecta Nominal Pipe Size and Pipe Schedule to input an estimated valuefor the meter tube diameter (English units only).4.If necessary, edit the Meter Tube Material.5.Enter the Line Size and select the Beta of the conditioning orificeplate. The required primary element sizing parameters will bedifferent depending on what primary element was selected.6.If necessary, select a primary element Material from the dropdownmenu.7.Select Next > to advance to the Save/Send Configuration tab.NoteTo be in compliance with appropriate national or internationalstandards, beta ratios and differential producer diameters should bewithin the limits as listed in the applicable standards. TheEngineering Assistant software will alert the user if a primary element value exceeds these limits, but will allow the user to proceed with the flow configuration.7.7Save/send configurationThe Save/Send Configuration tab shown in Figure 7-7 allows you to verify,save, and send the configuration information to the transmitter with thefully compensated mass and energy flow feature board.Procedure1.Review the information under the Flow Configuration and DeviceConfiguration headings.NoteFor more information, see Verifying device configuration.Figure 7-7: Save/Send Configuration Tab2.Select the icon above each window to edit the configurationinformation in these windows.NoteThe user will be notified if the configuration has been modified sinceit was last sent to the transmitter. A warning message will be shownto the right of the Send Flow Data and/or Send Transmitter Data checkboxes.3.To send the configuration, select the Send To button.NoteThe Send Flow Data and Send Transmitter Data check boxes can beused to select what configuration data is sent to the transmitter. Ifeither check box is unselected, the corresponding data will not besent.4.The Engineering Assistant Device Connection screen will appear, seeFigure 7-8.Figure 7-8: Engineering Assistant Device Connection Screen5.Select the Search button located in the lower right hand corner ofthe screen. Engineering Assistant will begin to search for connected devices.6.When the search is completed, select the device to communicatewith and select Send Configuration button.NoteAfter the configuration is sent to the device, saving the configuration file is recommended. The user can select the Save button on theSave/Send screen or select Save from the program menu.Once the configuration is finished being sent to the device, the user will be notified by a pop-up dialog box.7.If finished with the configuration process, close EngineeringAssistant.8Verifying device configurationUse Rosemount 3051SMV Engineering Assistant or any HART-compliantmaster to communicate with and verify configuration of the Rosemount3051SMV.Table 8-1 shows the Field Communicator fast keys for the fully compensatedmass and energy flow. Table 8-2 shows the Fast Keys for the direct processvariable output.NoteDevice configuration procedures are given for Rosemount 3051SMVEngineering Assistant 6.1 or later and AMS Device Manager 9.0 or later in theRosemount 3051SMV Reference Manual.A check (✓) indicates the basic configuration parameters. At a minimum,these parameters should be verified as part of the configuration and startupprocedure.Table 8-1: Fast Keys for Fully Compensated Mass and Energy FlowTable 8-2: Fast Keys for Direct Process Variable Output9Trimming the transmitterTransmitters are shipped fully calibrated per request or by the factorydefault of full scale.9.1Zero trimA zero trim is a single-point adjustment used for compensating mountingposition and line pressure effects on static and differential pressure sensors.When performing a zero trim, ensure that the equalizing valve is open andall wet legs are filled to the correct level.The transmitter will only allow up to five percent of URL zero error to betrimmed.9.1.1Perform a zero trim using the Field CommunicatorProcedure1.Equalize or vent the transmitter and connect the FieldCommunicator (for more information on connecting,see Figure 5-1).2.If the device is equipped with a static pressure sensor, zero the sensorby inputting the following Fast Key sequence at the Rosemount3051SMV menu:e the zero trim (selection 1) for a transmitter equipped with a gagestatic pressure sensor or lower sensor trim (selection 2) for atransmitted equipped with an absolute static pressure sensor.NoteWhen performing a lower sensor trim on an absolute pressuresensor, it is possible to degrade the performance of the sensor ifinaccurate calibration equipment is used. Use a barometer that is atleast three times as accurate as the absolute sensor of thetransmitter.4.Zero the differential pressure sensor by inputting the following FastKey sequence at the Rosemount 3051SMV menu:10Safety instrumented systems installation For safety certified installations, refer to the appropriate reference manualfor the installation procedure and system requirements:•For DP only measurements (measurement type D) refer to theRosemount 3051S Reference Manual.•For MultiVariable measurements (measurement type 1–7) refer to the Rosemount 3051SMV Reference Manual.11Product certifications11.1Rosemount 3051SMV/3051SFxRev 2.10European directive informationA copy of the EC Declaration of Conformity can be found at the end of theQuick Start Guide. The most recent revision of the EC Declaration ofConformity can be found at /Rosemount.Ordinary location certificationAs standard, the transmitter has been examined and tested to determinethat the design meets the basic electrical, mechanical, and fire protectionrequirements by a nationally recognized test laboratory (NRTL) as accreditedby the Federal Occupational Safety and Health Administration (OSHA).Installing Equipment in North AmericaThe US National Electrical Code (NEC) and the Canadian Electrical Code(CEC) permit the use of Division marked equipment in Zones and Zonemarked equipment in Divisions. The markings must be suitable for the areaclassification, gas, and temperature class. This information is clearly definedin the respective codes.11.1.1USAE5 US Explosionproof (XP) and Dust-Ignitionproof (DIP)Certificate FM16US0089XStandards FM Class 3600 – 2011, FM Class 3615 – 2006, FM Class 3616 –2011, FM Class 3810 – 2005, ANSI/NEMA 250 – 2003 Markings XP CL I, DIV 1, GP B, C, D; T5; DIP CL II, DIV 1, GP E, F, G; CL III;T5(–50 °C ≤ T a ≤ +85 °C); Factory Sealed; Type 4XI5 US Intrinsically Safe (IS) and Nonincendive (NI)Certificate FM16US0233Standards FM Class 3600 –2011, FM Class 3610 – 2007, FM Class 3611 –2004, FM Class 3616 – 2006, FM Class 3810 – 2005, NEMA250 – 1991Markings IS CL I, DIV 1, GP A, B, C, D; CL II, DIV 1, GP E, F, G; Class III; Class1, Zone 0 AEx ia IIC T4; NI CL 1, DIV 2, GP A, B, C, D; T4(–50 °C ≤T a ≤ +70 °C) when connected per Rosemount drawing03151-1206; Type 4XNoteTransmitters marked with NI CL 1, DIV 2 can be installed in Division 2locations using general Division 2 wiring methods or Nonincendive FieldWiring (NIFW). See Drawing 03151-1206.US Intrinsic Safety (IS) and Nonincendive (NI)Certificate:1143113Standards:FM Class 3600:2011, FM Class 3610:2010, FM Class3611:2004, FM Class 3810:2005, UL50E (1st Ed.)Markings:IS Class I/II/III, Division 1, Groups A, B, C, D, T4/ E, F, and GT135 °C; Class I, Zone 0 AEx ia IIC T4 Ga;T4 (-50 °C ≤ T a ≤ +70 °C) [HART];T4 (-50 °C ≤ T a ≤ +60 °C) [Fieldbus];when connected per Rosemount drawing 03151-1207; Type4XIE US FISCO Intrinsically SafeCertificate FM16US0233Standards FM Class 3600 – 2011, FM Class 3610 – 2010, FM Class 3611 –2004, FM Class 3616 – 2006, FM Class 3810 – 2005, NEMA250 – 1991Markings IS CL I, DIV 1, GP A, B, C, D; T4(–50 °C ≤ Ta ≤ +70 °C); whenconnected per Rosemount drawing 03151-1006; Type 4X US FISCO Intrinsically SafeCertificate:1143113Standards:FM Class 3600:2011, FM Class 3610:2010, FM Class3611:2004, FM Class 3810:2005, UL50E (1st Ed.)Markings:IS Class I/II/III, Division 1, Groups A, B, C, D, T4/ E, F, and GT135 °C; Class I, Zone 0 AEx ia IIC T4 Ga;T4 (-50 °C ≤ T a ≤ +70 °C) [HART];T4 (-50 °C ≤ T a ≤ +60 °C) [Fieldbus];when connected per Rosemount drawing 03151-1207; Type4X11.1.2CanadaE6 Canada Explosionproof, Dust Ignition-proof, Division 2Certificate1143113。

产品说明书00813-0106-4001, Rev WE2023 年 4 月Rosemount™ 3051 压力变送器通过 Rosemount 3051 压力变送器，您将更有效地控制工厂，能够在众多压力、液位和流量应用中借助我们的产品，减少产品变化和复杂性，降低总拥有成本。

您将可以访问各种信息，方便您进行诊断、校正甚至防止出现问题。

以我们无与伦比的可靠性和丰富的经验打造的 Rosemount 3051 符合行业标准，可帮助您以更高的效率和安全性标准进行工作，从而保持全球竞争力。

Rosemount 30512023 年 4 月内容建立压力测量标准 (2)Rosemount 3051C 共平面压力变送器订购信息 (6)Rosemount 3051T 直连式变送器订购信息 (18)Rosemount 3051CF 流量计选择指南 (28)Rosemount 3051L 液位变送器订购信息 (62)技术规格 (74)Rosemount 3051 产品认证 (91)尺寸图 (92)选项外， (106)建立压力测量标准经实践检验的一流性能、可靠性和安全性■超千万装机量■参考精度为量程的 0.04%■安装总性能为量程的 0.14%■稳定性可保持在 URL 的 0.1% 长达 12 年■SIL 2/3 认证（IEC 61508）Coplanar ™平台增强安装和应用灵活性■通过集成的压差流量计、压差液位解决方案和一体化阀组提高可靠性和性能。

■安装方便，所有方案都全面组合，并经过渗漏测试和标定。

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高级功能Bluetooth ® 技术■提高生产力、可靠性和人员安全性。

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■快速组态、检修和排除故障，所有设备对技术人员触手可及，速度比传统 HART ® 连接快十倍。

诊断■回路完整性诊断将连续地监测电路，检测影响通讯信号的问题，并提供腐蚀、外罩进水或电源不稳定等警报。

副本压力、差压变送器运行维护手册艾默生过程控制有限公司概述 (4)产品型号 (4)产品新特性 (5)第二章设备启动,运行和停运的操作程序及注意事项 (7)将回路设定至手动方式调整 (7)快键指令序列 (7)组态模拟输出参考 (7)设定过程变量单位 (8)设定输出方式 (8)重设量程 (8)只用手操器重设量程 (8)用压力输入源和手操器重设量程 (9)利用压力输入源与本机零点和量程按钮重设量程 (9)本机量程和零点控制 (10)设定阻尼 (10)LCD液晶表头选择 (10)诊断和检修 (11)变送器测试 (11)回路测试 (11)校验 (12)校验传感器 (13)校验4-20毫安输出 (13)确定校验频率 (13)传感器微调 (15)零点微调 (15)完全微调 (16)模拟输出微调 (16)数/模微调 (16)使用其它标尺进行数/模微调 (17)第三章设备安装,拆卸,维护的程序和注意事项 (21)安装流程图 (21)机械方面考虑事项 (22)安装支架 (22)外壳旋转 (23)安装要求 (23)液体流量测量 (23)气体流量测量 (23)蒸汽流量测量 (24)电气方面考虑事项 (24)电源 (24)接线图 (26)第四章设备连锁和保护功能说明 (28)故障模式报警 (28)3051型故障检修图 (31)第六章设备零部件及易损件 (32)变送器量程和传感器极限值 (32)螺栓的识别和安装 (33)3051C型典型型号结构 (34)第七章HART手操器 (39)开机 (39)组态 (40)修改单位 (41)修改量程 (42)修改阻尼值 (44)调校及故障诊断设置 (44)HART手操器快键指令序列 (49)第一章设备概述概述本部分概述了本手册所涉及的型号及手册指南。

警告！下述局限性可能会妨碍您进行安全或者有效的操作。

关键参数测量场合应有适当的故障诊断和备用系统。

压力变送器内含有一种灌充液，它用于将过程压力通过隔离膜片传送至压力传感器元件上。

产品说明书00813-0106-4016, Rev UC2023 年 3 月Rosemount™差压液位变送器和 1199 远传密封件应用■液位、流量、压力、界面、密度■极热和极冷环境■腐蚀、堵塞或粘滞过程■卫生要求■特殊过程连接件成熟、可靠和创新的技术使用资产位号随时获取信息新发运设备包含一个唯一的二维码资产位号，您可以通过它直接从设备访问序列化信息。

通过此功能，您可以：■在您的 MyEmerson 账号上访问设备图纸、图表、技术文档和故障排除信息■优化维修和保持效率的平均时间■确保您定位了正确的设备■省去耗时的先定位和抄录铭牌再查看资产信息的工作罗斯蒙特液位变送器此液位变送器将世界先进的罗斯蒙特压力仪表与直接安装密封件相结合，全部集成为一个型号。

Rosemount 3051SAL、3051L 和 2051L型液位变送器■全焊接系统具备突出的系统可靠性■无线组态提供新数据访问■使用全面的过程连接产品、灌充液、直接安装或毛细管连接件和材料可连接到几乎任何过程■利用 QZ 选件量化和优化整个系统的性能内容成熟、可靠和创新的技术 (2)Rosemount 3051S 电子远程传感器 (ERS™) 系统 (6)Rosemount 3051S Scalable™液位变送器 (26)用于 Rosemount 3051SAL 的法兰密封件 (40)Rosemount 3051L 液位变送器订购信息 (65)Rosemount 2051L 液位变送器 (77)直接安装式密封系统订购信息 (86)远传安装式密封系统订购信息 (92)法兰密封件 (98)螺纹密封件 (123)卫生型密封件 (129)专业密封件 (144)技术规格 (153)产品认证 (173)尺寸图 (216)2023 年 3 月/Rosemount罗斯蒙特 Tuned-System ™ 组件优化结果罗斯蒙特 Tuned-System 组件在高压连接件上采用直接安装密封件，在低压连接件上则采用远程安装（毛细管式）密封件。

数字化•智能压力/差压变送器DIGITAL•INTELLIGENT PRESSURE/DIFFERENCE PRESSURE TRANSMITTER1.变送器调检前请水平放置。

2.微量程变送器安装至现场后，应对变送器调零。

3.变送器应安装在干燥的环境中，切忌雨水冲刷。

在恶劣环境下，露天安装应使用变送器保护箱。

4.禁止用户自行拆装。

5.请用户自行检查变送器供电电压是否稳定和洁净（电源应防止交流干扰）。

6.经防爆检验合格的产品，不得随意更换元件或改变结构。

7.变送器外接地螺钉须可靠接大地。

8.本安型变送器外配安全栅的安装使用须按其使用说明书进行。

9.当本安防爆型变送器在爆炸危险环境区使用时，向安全栅供电的电源变压器须符合GB3836、4-2000标准8.1来要求。

10.S-PORT通信口必须使用我公司专用转接模块。

开箱后请用户仔细阅读本使用手册！简介 ．．．．．．．．．．．．．．．．．．5 1概述1.1整机外形 ．．．．．．．．．．．．．．61.2整机结构 ．．．．．．．．．．．．．．71.3工作原理简介 ．．．．．．．．．．．．8 2安装使用2.1整机外形尺寸图 ．．．．．．．．．．．92.2现场安装 ．．．．．．．．．．．．．．102.2.1安装方式 ．．．．．．．．．．．．102.2.2引压方式 ．．．．．．．．．．．．102.2.3排气/液阀 ．．．．．．．．．．．122.2.4盖子锁 ．．．．．．．．．．．．．122.2.5流程连接孔距离调整 ．．．．．．．122.2.6安装注意事项 ．．．．．．．．．．142.3与测量方式相关问题 ．．．．．．．．．142.4电气安装 ．．．．．．．．．．．．．．172.5本安防爆型变送器系统接线图 ．．．．．192.6隔爆型变送器说明 ．．．．．．．．．．19 3调试与操作3.1概述 ．．．．．．．．．．．．．．．．203.1.1各键的定义 ．．．．．．．．．．．213.1.2各键的功能描述 ．．．．．．．．．223.1.3工作状态显示 ．．．．．．．．．．223.1.4菜单描述 ．．．．．．．．．．．．223.1.5符号的输入 ．．．．．．．．．．．233.1.6整数的输入 ．．．．．．．．．．．233.1.7小数的输入 ．．．．．．．．．．．23 3.2变送器准确度微调 ．．．．．．．．．．24数字化•智能压力/差压变送器使用手册3.3主菜单说明 ．．．．．．．．．．．．．253.4子菜单操作详细说明 ．．．．．．．．．264用户维护4.1概述 ．．．．．．．．．．．．．．．．334.2软维护 ．．．．．．．．．．．．．．．334.3硬维护 ．．．．．．．．．．．．．．．344.4故障排除 ．．．．．．．．．．．．．．355 法兰变送器安装使用说明5.1 概述 ．．．．．．．．．．．．．．．385.2 品种规格 ．．．．．．．．．．．．．385.3 仪表的调校 ．．．．．．．．．．．．425.4 仪表的使用方法 ．．．．．．．．．．425.5 仪表维护 ．．．．．．．．．．．．．495.6 订货须知 ．．．．．．．．．．．．．49附录A.1性能指标 ．．．．．．．．．．．．．．52A.1.1技术指标 ．．．．．．．．．．．．52A.1.2使用条件 ．．．．．．．．．．．．55A.2随机附件 ．．．．．．．．．．．．．．56A.3注意事项 ．．．．．．．．．．．．．．56数字化•智能压力/差压变送器是在采用世界先进的、成熟的、可靠的电容传感器技术基础上，结合先进的单片计算机技术和传感器数字转换技术精心设计而成的多功能数字化•智能仪表。